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Reconciling extragalactic star formation efficiencies with theory : Insights from PHANGS

Meidt, Sharon E. ; Glover, Simon C.O. ; Klessen, Ralf S. ; Leroy, Adam K. ; Sun, Jiayi ; Agertz, Oscar LU ; Emsellem, Eric ; Henshaw, Jonathan D. ; Neumann, Lukas and Rosolowsky, Erik , et al. (2025) In Astronomy and Astrophysics 700.
Abstract

New extragalactic measurements of the cloud population-averaged star formation efficiency per free-fall time, Ïμff, from PHANGS show little sign of a theoretically predicted dependence on the gas virial level and weak variation with cloud-scale gas velocity dispersion. We explore ways to bring theory into consistency with the observations, particularly by highlighting systematic variations in internal density structure that must accompany an increase in virial parameter typically found toward denser galaxy centers. To introduce these variations into conventional turbulence-regulated star formation models, we adopted three adjustments, all motivated by the expectation that the background host galaxy has an influence on the... (More)

New extragalactic measurements of the cloud population-averaged star formation efficiency per free-fall time, Ïμff, from PHANGS show little sign of a theoretically predicted dependence on the gas virial level and weak variation with cloud-scale gas velocity dispersion. We explore ways to bring theory into consistency with the observations, particularly by highlighting systematic variations in internal density structure that must accompany an increase in virial parameter typically found toward denser galaxy centers. To introduce these variations into conventional turbulence-regulated star formation models, we adopted three adjustments, all motivated by the expectation that the background host galaxy has an influence on the cloud scale: (1) We incorporate self-gravity and an internal density distribution that contains a broad power-law (PL) component and resembles the structure observed in local resolved clouds; (2) We allow the internal gas kinematics to include motion in the background potential and let this regulate the onset of self-gravitation; (3) We assume that the distribution of gas densities is in a steady state for only a fraction of a cloud free-fall time. In practice, these changes significantly reduce the efficiencies predicted in multi-free-fall (MFF) scenarios compared to purely lognormal probability density functions (PDFs) and tie efficiency variations to variations in the slope of the PL α. We fit the model to PHANGS measurements of Ïμff to identify the PL slopes that yield an optimal match. These slopes vary systematically with galactic environment in the sense that gas that sits furthest from virial balance contains fractionally more gas at high density. We relate this to the equilibrium response of gas in the presence of the galactic gravitational potential, which forces more gas to high density than characteristic of fully self-gravitating clouds. Viewing the efficiency variations as originating with time evolution in the PL slope, our findings would alternatively imply coordination of the cloud evolutionary stage within environment. With this galaxy regulation behavior included, our preferred self-gravitating multi-freefall sgMFF models function similarly to the original, roughly virialized cloud single-free-fall models. However, outside the environment of disks with their characteristic regulation, the flexible MFF models may be better suited.

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publishing date
type
Contribution to journal
publication status
published
subject
keywords
Galaxies: ISM, Galaxies: star formation, ISM: clouds
in
Astronomy and Astrophysics
volume
700
article number
A123
publisher
EDP Sciences
external identifiers
  • scopus:105013197343
ISSN
0004-6361
DOI
10.1051/0004-6361/202453564
language
English
LU publication?
yes
id
95ba9abe-1d01-43e0-bcda-a60db5cef119
date added to LUP
2025-11-10 13:52:24
date last changed
2025-11-10 13:52:43
@article{95ba9abe-1d01-43e0-bcda-a60db5cef119,
  abstract     = {{<p>New extragalactic measurements of the cloud population-averaged star formation efficiency per free-fall time, Ïμ<sub>ff</sub>, from PHANGS show little sign of a theoretically predicted dependence on the gas virial level and weak variation with cloud-scale gas velocity dispersion. We explore ways to bring theory into consistency with the observations, particularly by highlighting systematic variations in internal density structure that must accompany an increase in virial parameter typically found toward denser galaxy centers. To introduce these variations into conventional turbulence-regulated star formation models, we adopted three adjustments, all motivated by the expectation that the background host galaxy has an influence on the cloud scale: (1) We incorporate self-gravity and an internal density distribution that contains a broad power-law (PL) component and resembles the structure observed in local resolved clouds; (2) We allow the internal gas kinematics to include motion in the background potential and let this regulate the onset of self-gravitation; (3) We assume that the distribution of gas densities is in a steady state for only a fraction of a cloud free-fall time. In practice, these changes significantly reduce the efficiencies predicted in multi-free-fall (MFF) scenarios compared to purely lognormal probability density functions (PDFs) and tie efficiency variations to variations in the slope of the PL α. We fit the model to PHANGS measurements of Ïμ<sub>ff</sub> to identify the PL slopes that yield an optimal match. These slopes vary systematically with galactic environment in the sense that gas that sits furthest from virial balance contains fractionally more gas at high density. We relate this to the equilibrium response of gas in the presence of the galactic gravitational potential, which forces more gas to high density than characteristic of fully self-gravitating clouds. Viewing the efficiency variations as originating with time evolution in the PL slope, our findings would alternatively imply coordination of the cloud evolutionary stage within environment. With this galaxy regulation behavior included, our preferred self-gravitating multi-freefall sgMFF models function similarly to the original, roughly virialized cloud single-free-fall models. However, outside the environment of disks with their characteristic regulation, the flexible MFF models may be better suited.</p>}},
  author       = {{Meidt, Sharon E. and Glover, Simon C.O. and Klessen, Ralf S. and Leroy, Adam K. and Sun, Jiayi and Agertz, Oscar and Emsellem, Eric and Henshaw, Jonathan D. and Neumann, Lukas and Rosolowsky, Erik and Schinnerer, Eva and Utomo, Dyas and Van Der Wel, Arjen and Bigiel, Frank and Colombo, Dario and Gleis, Damian R. and Grasha, Kathryn and Gensior, Jindra and Gnedin, Oleg Y. and Hughes, Annie and Murphy, Eric J. and Querejeta, Miguel and Smith, Rowan J. and Williams, Thomas G. and Usero, Antonio}},
  issn         = {{0004-6361}},
  keywords     = {{Galaxies: ISM; Galaxies: star formation; ISM: clouds}},
  language     = {{eng}},
  publisher    = {{EDP Sciences}},
  series       = {{Astronomy and Astrophysics}},
  title        = {{Reconciling extragalactic star formation efficiencies with theory : Insights from PHANGS}},
  url          = {{http://dx.doi.org/10.1051/0004-6361/202453564}},
  doi          = {{10.1051/0004-6361/202453564}},
  volume       = {{700}},
  year         = {{2025}},
}